Difference between revisions of "Basis for a topology"
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| − | {{Refactor notice|grade=A|msg=Updating with findings.}} | + | {{Refactor notice|grade=A|msg=Updating with findings. |
| + | * Need to add: [[A function is continuous if and only if the pre-image of every basis element is open]] - [[User:Alec|Alec]] ([[User talk:Alec|talk]]) 18:35, 17 December 2016 (UTC)}} | ||
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==Definition== | ==Definition== | ||
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We do not do these because it (sort of) violates the [[Doctrine of Least Surprise]], we usually deal with subsets of the ''space'' not subsets of the ''[[set system]]'' on that space.<br/> | We do not do these because it (sort of) violates the [[Doctrine of Least Surprise]], we usually deal with subsets of the ''space'' not subsets of the ''[[set system]]'' on that space.<br/> | ||
That is a weird way of saying if we have a structure (eg [[topological space]], [[measurable space]], so forth) say {{M|(A,\mathcal{B})}} we usually deal with (collections of) subsets of {{M|A}} and specify they must be in {{M|\mathcal{B} }}.</ref>. We say {{M|\mathcal{B} }} is ''a basis for the [[topology]] {{M|\mathcal{J} }}'' if both of the following are satisfied: | That is a weird way of saying if we have a structure (eg [[topological space]], [[measurable space]], so forth) say {{M|(A,\mathcal{B})}} we usually deal with (collections of) subsets of {{M|A}} and specify they must be in {{M|\mathcal{B} }}.</ref>. We say {{M|\mathcal{B} }} is ''a basis for the [[topology]] {{M|\mathcal{J} }}'' if both of the following are satisfied: | ||
| − | # {{M|1=\forall B\in\mathcal{B}[B\in\mathcal{J}]}} | + | # {{M|1=\forall B\in\mathcal{B}[B\in\mathcal{J}]}} - every element of {{M|\mathcal{B} }} is an [[open set]] of {{Top.|X|J}} |
| − | # {{M|1=\forall U\in\mathcal{J}\exists\{B_\alpha\}_{\alpha\in I}\subseteq\mathcal{B}[\bigcup_{\alpha\in I}B_\alpha=U]}} | + | # {{M|1=\forall U\in\mathcal{J}\exists\{B_\alpha\}_{\alpha\in I}\subseteq\mathcal{B}[\bigcup_{\alpha\in I}B_\alpha=U]}} - every [[open set]] in {{Top.|X|J}} is the [[union]] of some arbitrary family of basis elements<ref group="Note">The elements of {{M|\mathcal{B} }} are called ''basis elements''. This is mentioned later in the article</ref> |
| + | The elements of {{M|\mathcal{B} }} are called ''basis elements''. | ||
| + | |||
| + | =={{link|Basis criterion|topology}}== | ||
| + | {{:The basis criterion (topology)/Statement}} | ||
==[[Topology generated by a basis]]== | ==[[Topology generated by a basis]]== | ||
{{:Topology generated by a basis/Statement}} | {{:Topology generated by a basis/Statement}} | ||
Latest revision as of 18:35, 17 December 2016
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Updating with findings.
- Need to add: A function is continuous if and only if the pre-image of every basis element is open - Alec (talk) 18:35, 17 December 2016 (UTC)
Contents
[hide]Definition
Let (X,\mathcal{ J }) be a topological space and let \mathcal{B}\in\mathcal{P}(\mathcal{P}(X)) be any collection of subsets of X[Note 1]. We say \mathcal{B} is a basis for the topology \mathcal{J} if both of the following are satisfied:
- \forall B\in\mathcal{B}[B\in\mathcal{J}] - every element of \mathcal{B} is an open set of (X,\mathcal{ J })
- \forall U\in\mathcal{J}\exists\{B_\alpha\}_{\alpha\in I}\subseteq\mathcal{B}[\bigcup_{\alpha\in I}B_\alpha=U] - every open set in (X,\mathcal{ J }) is the union of some arbitrary family of basis elements[Note 2]
The elements of \mathcal{B} are called basis elements.
Basis criterion
Let (X,\mathcal{ J }) be a topological space and let \mathcal{B}\in\mathcal{P}(\mathcal{P}(X)) be a topological basis for (X,\mathcal{ J }). Then[1]:
- \forall U\in\mathcal{P}(X)\big[U\in\mathcal{J}\iff\underbrace{\forall p\in U\exists B\in\mathcal{B}[p\in B\subseteq U]}_{\text{basis criterion} }\big][Note 3]
If a subset U of X satisfies[Note 4] \forall p\in U\exists B\in\mathcal{B}[p\in B\subseteq U] we say it satisfies the basis criterion with respect to \mathcal{B} [1]
Topology generated by a basis
Let X be a set and let \mathcal{B}\in\mathcal{P}(\mathcal{P}(X)) be any collection of subsets of X, then:
- (X,\{\bigcup\mathcal{A}\ \vert\ \mathcal{A}\in\mathcal{P}(\mathcal{B})\}) is a topological space with \mathcal{B} being a basis for the topology \{\bigcup\mathcal{A}\ \vert\ \mathcal{A}\in\mathcal{P}(\mathcal{B})\}
- we have both of the following conditions:
- \bigcup\mathcal{B}=X (or equivalently: \forall x\in X\exists B\in\mathcal{B}[x\in B][Note 5]) and
- \forall U,V\in\mathcal{B}\big[U\cap V\neq\emptyset\implies \forall x\in U\cap V\exists B\in\mathcal{B}[x\in W\wedge W\subseteq U\cap V]\big][Note 6]
- Caveat:\forall U,V\in\mathcal{B}\ \forall x\in U\cap V\ \exists W\in\mathcal{B}[x\in W\subseteq U\cap V] is commonly said or written; however it is wrong, this is slightly beyond just abuse of notation.[Note 7]
See also
Notes
- Jump up ↑ We could say something else instead of \mathcal{B}\in\mathcal{P}(\mathcal{P}(X)):
- Let \mathcal{B}\in\mathcal{P}(\mathcal{J}) - so \mathcal{B} is explicitly a collection of open sets, then we could drop condition 1. Or!
- Let \mathcal{B}\subseteq\mathcal{J} . But it is our convention to not say "let A\subseteq B" but "let A\in\mathcal{P}(B)" instead. To emphasise that the power-set is possibly in play.
That is a weird way of saying if we have a structure (eg topological space, measurable space, so forth) say (A,\mathcal{B}) we usually deal with (collections of) subsets of A and specify they must be in \mathcal{B} . - Jump up ↑ The elements of \mathcal{B} are called basis elements. This is mentioned later in the article
- Jump up ↑ Note that when we write p\in B\subseteq U we actually mean p\in B\wedge B\subseteq U. This is a very slight abuse of notation and the meaning of what is written should be obvious to all without this note
- Jump up ↑ This means "if a U\in\mathcal{P}(X) satisfies...
- Jump up ↑ By the implies-subset relation \forall x\in X\exists B\in\mathcal{B}[x\in B] really means X\subseteq\bigcup\mathcal{B} , as we only require that all elements of X be in the union. Not that all elements of the union are in X. However:
- \mathcal{B}\in\mathcal{P}(\mathcal{P}(X)) by definition. So clearly (or after some thought) the reader should be happy that \mathcal{B} contains only subsets of X and he should see that we cannot as a result have an element in one of these subsets that is not in X.
- We then use Union of subsets is a subset of the union (with B_\alpha:\eq X) to see that \bigcup\mathcal{B}\subseteq X - as required.
- Jump up ↑ We could of course write:
- \forall U,V\in\mathcal{B}\ \forall x\in \bigcup\mathcal{B}\ \exists W\in\mathcal{B}[(x\in U\cap V)\implies(x\in W\wedge W\subseteq U\cap V)]
- Jump up ↑ Suppose that U,V\in\mathcal{B} are given but disjoint, then there are no x\in U\cap V to speak of, and x\in W may be vacuously satisfied by the absence of an X, however:
- x\in W\subseteq U\cap V is taken to mean x\in W and W\subseteq U\cap V, so we must still show \exists W\in\mathcal{B}[W\subseteq U\cap V]
- This is not always possible as W would have to be \emptyset for this to hold! We do not require \emptyset\in\mathcal{B} (as for example in the metric topology)
- x\in W\subseteq U\cap V is taken to mean x\in W and W\subseteq U\cap V, so we must still show \exists W\in\mathcal{B}[W\subseteq U\cap V]
References
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OLD PAGE
Definition
Let X be a set. A basis for a topology on X is a collection of subsets of X, \mathcal{B}\subseteq\mathcal{P}(X) such that[1]:
- \forall x\in X\exists B\in\mathcal{B}[x\in B] - every element of X belongs to at least one basis element.
- \forall B_1,B_2\in\mathcal{B},x\in X\ \exists B_3\in\mathcal{B}[x\in B_1\cap B_2\implies(x\in B_3\wedge B_3\subseteq B_1\cap B_2)][Note 1] - if any 2 basis elements have non empty intersection, there is a basis element within that intersection containing each point in it.
Note that:
- The elements of \mathcal{B} are called basis elements[1]
Topology generated by \mathcal{B}
If \mathcal{B} is such a basis for X, we define the topology \mathcal{J} generated by \mathcal{B} [1] as follows:
- A subset of X, U\subseteq X is considered open (equivalently, U\in\mathcal{J} ) if:
- \forall x\in U\exists B\in\mathcal{B}[x\in B\wedge B\subseteq U][Note 2]
[Expand]
Claim: This \mathcal{(J)} is indeed a topology
See also
Notes
- Jump up ↑ This is a great example of a hiding if-and-only-if, note that:
- (x\in B_3\wedge B_3\subseteq B_1\cap B_2)\implies x\in B_1\cap B_2 (by the implies-subset relation) so we have:
- (x\in B_3\wedge B_3\subseteq B_1\cap B_2)\implies x\in B_1\cap B_2\implies(x\in B_3\wedge B_3\subseteq B_1\cap B_2)
- Thus (x\in B_3\wedge B_3\subseteq B_1\cap B_2)\iff x\in B_1\cap B_2
- (x\in B_3\wedge B_3\subseteq B_1\cap B_2)\implies x\in B_1\cap B_2 (by the implies-subset relation) so we have:
- Jump up ↑ Note that each basis element is itself is open. This is because U is considered open if forall x, there is a basis element containing x with that basis element \subseteq U, if U is itself a basis element, it clearly satisfies this as B\subseteq B
TODO: Make this into a claim
References
- ↑ Jump up to: 1.0 1.1 1.2 Topology - Second Edition - James R. Munkres
